synapses - sinoe medical association
TRANSCRIPT
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Neurophysiology
Danil Hammoudi.MD
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SYNAPSESSYNAPSES
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SynapsesSynapses
The site at which neurons communicate is called a The site at which neurons communicate is called a synapse,
a cell junction that mediates the transfer of information a cell junction that mediates the transfer of information from one neuron to the next
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SynapsesSynapses
Because signals pass across most synapses in one Because signals pass across most synapses in one direction only, synapses determine the direction of information flow throughout the nervous systemg y
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SynapsesSynapses
The neuron the conducts impulses toward a synapse is The neuron the conducts impulses toward a synapse is called the presynaptic neuron
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SynapsesSynapses
The neuron that conducts impulses away from the The neuron that conducts impulses away from the synapse is called the postsynaptic neuron
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SynapsesSynapsesMost neurons function as presynaptic (information sending) and postsynaptic (information receiving neurons
In essence they get information from some neurons and dispatch it to othersdispatch it to others
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SynapsesSynapses
Most synapses occur between the axon terminals of one d th d d it f th neuron and the dendrites of another axons
These are called axodendritic synapses
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SynapsesSynapses
Less common and far less understood are:Less common, and far less understood, are:
synapses between two axons (axoaxonic),
between two dendrites (dendrodendritic)between two dendrites (dendrodendritic)
between a dendrite and a cell body (dendosomatic)
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Types of Synapses
§ Axodendritic – synapses between the axon of one neuron and the§ Axodendritic – synapses between the axon of one neuron and the dendrite of another
§ Axosomatic – synapses between the axon of one neuron and the soma of another
§ Other types of synapses include:§ Other types of synapses include:§ Axoaxonic (axon to axon)§ Dendrodendritic (dendrite to dendrite)§ Dendrosomatic (dendrites to soma)
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2 FUNCTIONAL TYPE OF SYNAPSES2 FUNCTIONAL TYPE OF SYNAPSESElectrical Synapses Chemical Synapsesy p§ Electrical synapses:§ Are less common than chemical synapses
Chemical Synapses§ Specialized for the release and reception of neurotransmitters
y p§ Correspond to gap junctions found in other cell types§ Are important in the CNS in:
§ Typically composed of two parts:
§ Axonal terminal of the presynaptic neuron which contains synapticp
§ Arousal from sleep§ Mental attention§ Emotions and memory§ Ion and water homeostasis
neuron, which contains synaptic vesicles
§ Receptor region on the dendrite(s) or f th t ti§ Ion and water homeostasis soma of the postsynaptic neuron
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SynapsesSynapsesStructurally synapses are l b ll elaborate cell
junctions
At the typical ypaxodendritic synapse the presynaptic axon presynaptic axon terminal contain synaptic vesicles
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SynapsesSynapsesSynaptic vesicles are membrane bound sacs filled with molecular neurotransmitters
These molecules transmit signals across th the synapse
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SynapsesSynapsesMitochondria are abundant in the axon terminal as the secretion of
i neurotransmitters requires a great deal of energyenergy
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SynapsesSynapsesAt the synapse, the plasma membranes of the two neurons are separated by a synaptic l fcleft
On the under surfaces of th i ll the opposing cell membranes are dense materials; the pre- and materials; the pre and post- synaptic densities
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SynapsesSynapsesWhen an impulse travels along the axon of the presynaptic neuron, it signals the synaptic vesicles to fuse with the presynaptic membrane at the presynaptic density
The released neurotransmitter molecules diffuse across the The released neurotransmitter molecules diffuse across the synaptic cleft and bind to the postsynaptic membrane at the post synaptic densityp y p y
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SynapseSynapseThe binding of the two membranes changes the membrane charge on the postsynaptic neuron, influencing the generation of a nerve impulse or action potential in that neuronneuron
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Communication
Begins with the stimulation of a neuron.One neuron may be stimulated by another by a receptor cell or even by some One neuron may be stimulated by another, by a receptor cell, or even by some physical event such as pressure.
Once stimulated, a neuron will communicate information about ,the causative event.
Such neurons are sensory neurons and they provide info about both the y y pinternal and external environments.
Sensory neurons (a.k.a. afferent neurons) will send info to neurons in the brain and spinal cord There association neurons (a k a interneurons) will brain and spinal cord. There, association neurons (a.k.a. interneurons) will integrate the information and then perhaps send commands to motor neurons (efferent neurons) which synapse with muscles or glands.
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Neurotransmitters
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Neurotransmitters· Acetylcholine (AcH)· Dopamine (DA)· Histamine· Norepinephrine (NE) Norepinephrine (NE)· Epinephrine· Serotonin (5HT)
P tidPeptides· GammaAminobutyricAcid (GABA)· Glutamate· Aspartate· Glycine
NeuropeptidesNeuropeptides · Insulin· Betaendorphin· Neuropeptide Y· Calcitonin
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Types of NT
1.Acetylcholine (ACh) 1 this NT has 2 types of receptors1. this NT has 2 types of receptors A. nicotinic receptors:
a. agonist: is nicotine b. antagonist: is curare
B. muscarinic receptors: a. agonist: is muscarine b. antagonist: in atropine (deadly nightshadeb. antagonist: in atropine (deadly nightshade
2. deactivated by acetylcholinesterase (AChE) & choline is reused
3 h ti i i hibit AChE ( i t) b t i ibl3. physostigmine: inhibits AChE (agonist) but is reversible.
4. botulinum toxin prevents the release of ACH from the terminal button (antagonist)
5. black widow spider venom causes ACH terminals to release ACH (agonist)
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MonoaminesAll monoamines work thru metabotropic receptors p pMonoamine oxidase (MAO) & catechol-O-methyltransferase (COMT) deactivate
these. 1. The drug reserpine prevents the storage of the monoamines
types of monoamines:I. Indolamines: 1. Serotonin (5-HT)
A. produced in the raphe nuclei in the midline of the pons & medulla 2. B. the drug parachlorophenylalanine (PCPA) blocks tryptophan hydroxylase &
prevents the synthesis of 5-HT (an antagonist)synthesis of 5 HT (an antagonist)
C. iproniazid block MAO (agonists)
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II. Catecholamines: The amino acid tyrosine is the precursor NT is released thru axononal varicosities: swellings on the axon 1. Norepinephrine (NE) noradrenalin A. in the CNS this is produced in the locus ceruleus (nucleus in midbrain) &A. in the CNS this is produced in the locus ceruleus (nucleus in midbrain) &
is distributed though out the CNS
2. Epinephrine (E) adrenaline A k t th t NEA. works at the same receptors as NE B. stimulates the sympathetic nervous system C. ephedrine: alpha & beta receptor agonist D. propranolol: beta receptor blocker has antihypertensive effects p p p yp3 Dopamine (DA) A. produced in substantia nigra & ventral tegmental area (midbrain) & sent to
the cortex, limbic system, hypothalamus, & basal ganglia B implicated in movement disorders e g in Parkinson's disease (L DOPA)B. implicated in movement disorders e.g., in Parkinson s disease (L-DOPA) C. cocaine and amphetamine work by preventing reuptake D. apomorphine: stimulates only autoreceptors (an antagonist)
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CRITERIACRITERIANT found in axon terminals
NT released by action potentials
Synthesis identified
External application mimic normal Response
Pharmacology same for normal and externally applied NT ~
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L k & K M d lLock & Key ModelNT binds to receptor
NT = key
Receptor = lock
Receptor changes shape
determines if EPSP or IPSP
receptor subtypes
NOT NT ~
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ligand binds to receptorgactivation: + or - ~
NTNT
Receptor A
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Same NT can bind to different -R
different part of NT ~
NT
Receptor BReceptor A
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Specificity of drugs
NTDrug ADrug B
NT
Receptor BReceptor A
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Acetylcholine - ACh Acetylcholine ACh Most abundant NT in Peripheral N.S.
also found in Central N Salso found in Central N.S.
Precursor = cholinenutrient
Degraded by acetylcholinesterase-AChE
Membrane bound - pre- & postsynapticNicotinic receptor - ionotropicM i i t t b t i Muscarinic receptor - metabotropic ~
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Ach - Distrubution Ach Distrubution Peripheral N.S.Excites somatic muscleExcites somatic muscleAutonomic NS
Ganglia gParasympathetic NS
Neuroeffector junctionCentral N S widespreadCentral N.S. - widespread
HippocampusHypothalamus ~yp
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Cholinergic AgonistsCholinergic AgonistsDirect
Muscarine Nicotine
small dosessmall doses
IndirectAChE Inhibitors ~AChE Inhibitors
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AChE inhibitorsAChE inhibitorsPhysostigmine
Organophosphates - irreversibleDFPSoman & SarinMalathion*
A i t A t i t?Agonist or Antagonist?
indirect agonist ~
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Cholinergic AntagonistsCholinergic Antagonists
Direct
Nicotinic - Curare
Muscarinic - Atropine
Scopolamine
Indirect
Botulinum Toxin
Black Widow Spider Venom ~
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AChACh
A AChEBotulinum toxin
N M AChEBWSV
curare atropine
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MonaminesMonaminesAmino acid precursors
single amine group
2 groups
h l h lCatecholamines - catechol ring
Indolamine - indole ring
Aff d b f d Affected by many of same drugs ~
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MonoaminesMonoamines
Catecholamines Indolamines
Dopamine - DADopaminergic
Serotonin - 5-HTSerotonergic
Norepinephrine - NENoradrenergicg
Epinephrine - E Adrenergic ~ Adrenergic
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MonoaminesMonoamines
Terminated by...
reuptake
monoamine oxidase - MAO
h l O h l f COMTcatechol-O-methyltranferase - COMT
also in liver
R i > l k i l Reserpine ---> leaky vesicles
depletes monoamines ~
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MonoaminesMonoamines
MAOOReserpine
ACOMT
MAOCOMT
MAO
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Indirect Monoamine AgonistsIndirect Monoamine AgonistsMAOIs
Iproniazid
Reuptake blockersT i li tid tTricyclic antidepressants
ImipramineDesipramineDesipramineCocaine & Amphetamine ~
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DopamineDopamineOnly in central nervous system
mostly inhibitory systems
Reward
Schizophrenia
Movementl hNigrostriatal Pathway
At least 5 DA-R types: D1, D2, etc. ~
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Dopaminergic DrugsDopaminergic DrugsAgonist
L-dopa
AntagonistsChl iChlorpromazine
D1
HaloperidolpD2 ~
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N i h iNorepinephrinePeripheral N.S.
Sympathetic neuroeffector junctionAdrenal glands
C t l N SCentral N.S.HypothalamusLocus coeruleusLocus coeruleus
Alpha & Beta receptor subtypes NEα & NEβ ~β
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Noradrenergic DrugsNoradrenergic DrugsAgonists
Mescaline Ephedrine
A t i t Antagonist Propranalol -beta receptors ~beta receptors
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SerotoninSerotoninNOT a catecholamine
Peripheral
98% in blood & smooth muscle
Central N.S.
Raphe nucleus
Hypothalamus
R subtypes: 5HT1 & 5HT2 ~
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Sertonergic DrugsSertonergic DrugsAgonists
SSRIsSelective Serotonin Reuptake Inhibitors
BuspironeBuspironeMDMA
Ecstacy ~y
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Gamma-aminobutyric acidGamma aminobutyric acidGABA - GABAergic
M j NT i b i i hibit tMajor NT in brain inhibitory system
Receptor subtypes
GABA controls Cl channelGABAA - controls Cl- channel
GABAB - controls K+ channel
Precursor = glutamate ~Precursor = glutamate
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NeuropeptideNeuropeptide
Substance P - pain signaling
Endorphins - analgesia, euphoria ~
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EndorphinsEndorphinsOpioids
D hiDynorphin
met-enkephalinleu enkephalinleu-enkephalinBeta-endorphin
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E d hi ( t )Endorphins (cont.)Agonists
morphineheroincodeinecodeine
Antagonistsnaloxonenaloxonenaltrexone ~
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Other NTsOther NTsExcitatory amino acids
Gl & AGlutamate & Aspartate
HistamineInflammatory ResponseInflammatory Response
Nitric Oxide - It’s a gas
AnandamideAnandamide
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MODE OF ACTIONMODE OF ACTION
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Postsynaptic PotentialsPostsynaptic Potentials
§ Neurotransmitter receptors mediate changes in membrane potential according to:
§ The amount of neurotransmitter released§ Th t f ti th t itt i b d t t§ The amount of time the neurotransmitter is bound to receptors
§ The two types of postsynaptic potentials are:§ EPSP – excitatory postsynaptic potentials§ y p y p p§ IPSP – inhibitory postsynaptic potentials order
§ Spatial summation postsynaptic neuron is stimulated by a large number of§ Spatial summation – postsynaptic neuron is stimulated by a large number of terminals at the same time
§ IPSPs can also summate with EPSPs, canceling each other out
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Excitatory Postsynaptic Potentials(EPSP)Excitatory Postsynaptic Potentials(EPSP)
§§ EPSPs are graded potentials that can initiate an action potential in an axonEPSPs are graded potentials that can initiate an action potential in an axon§ U l h i ll t d h l§ Use only chemically gated channels§ Na + and K + flow in opposite directions at the same time
§§ Postsynaptic membranes do not generate action potentialsPostsynaptic membranes do not generate action potentials§§ y p g py p g p
Inhibitory Synapses and IPSPsInhibitory Synapses and IPSPs
§§ Neurotransmitter binding to a receptor at inhibitory synapses:Neurotransmitter binding to a receptor at inhibitory synapses:
§ Causes the membrane to become more permeable to potassium and chloride ions
§ Leaves the charge on the inner surface negative
§ Reduces the postsynaptic neuron’s ability to produce an action potential§ Reduces the postsynaptic neuron s ability to produce an action potential
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SummationSummation§ A single EPSP cannot induce an action potential
§ EPSPs must summate temporally or spatially to induce an action potential
§ Temporal summation – presynaptic neurons transmit impulses in rapidfire order
§ Spatial summation – postsynaptic neuron is stimulated by a large number of§ Spatial summation postsynaptic neuron is stimulated by a large number of terminals at the same time
§ IPSPs can also summate with EPSPs, canceling each other out
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The main membrane processes involved in neural activities The main membrane processes involved in neural activities are:are:
1 resting potential: the transmembrane potential of a resting1. resting potential: the transmembrane potential of a resting cell
2 d d t ti l t l li d h i th2. graded potential: a temporary localized change in the resting potential, caused by a stimulus
3. action potential: an electrical impulse (produced by the graded potential) that propagates along the surface of an axon to a synapseaxon to a synapse.
4. synaptic activity: the release of neurotransmitters at the ti b hi h d d d t ti lpresynaptic membrane, which produce graded potentials
in a postsynaptic membrane.
5. information processing: the response (integration of stimuli) of a postsynaptic cell.
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The 3 main requirements for a transmembrane potentialThe 3 main requirements for a transmembrane potential are:
1. A concentration gradient of ions (Na+, K+) across the cell membrane
2. The membrane be selectively permeable through membrane channels
3. Passive and active transport mechanisms maintain a difference in charge across the membrane (resting potential = -70 mV)
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Passive forces acting across the membrane are •chemical •electrical.
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1. Chemical gradients:-concentration gradients of ions (Na+ K+) across the-concentration gradients of ions (Na+, K+) across the membrane
2 El t i l di t2. Electrical gradients:- the charges of positive and negative ions are separated across the membrane, resulting in a potential difference.g p
- positive and negative charges attract one another- if charges are not separated they will move to eliminateif charges are not separated, they will move to eliminate potential difference, resulting in an electrical current
h h t b t i t i ll d it- how much current a membrane can restrict is called its resistance
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Electrochemical gradient:1. the sum of chemical and electrical forces acting on an gion (Na+, K+) across a cell membrane is the electrochemical gradient for that ion.
2. chemical gradient of potassium tends to move potassium out of the cell, but the electrical gradient of the
ll b thi tcell membrane opposes this movement
3. the transmembrane potential at which there is no net pmovement of a particular ion across the cell membrane is the equilibrium potential for that ion (K+ = -90 mV, Na+ = +66 mV)+66 mV).
4. the electrochemical gradient is a form of potential energy
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Active forces maintain the cell membrane’s resting potential (-70 mV).
The cell actively pumps out sodium ions (Na+), and pumps in potassium ions (K+).pumps in potassium ions (K+).
The sodium-potassium exchange pump (the carrier protein sodium potassium ATPase) powered by ATPprotein sodium-potassium ATPase), powered by ATP, exchanges 3 Na+ for each 2 K+, balancing the passive forces of diffusion.
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Relative Refractory PeriodyCould an AP be generated during the undershoot?
Yes! But it would take an initial stimulus that is much, much stronger than usual., g
WHY?
This situation is known as the relative refractory period.
Imagine, if you will, a toilet. g , y ,
When you pull the handle, water floods the bowl. This event takes a couple of seconds and you cannot stop it in the middle. Once the bowl empties the flush is complete Now the upper tank is empty Ifbowl empties, the flush is complete. Now the upper tank is empty. If you try pulling the handle at this point, nothing happens (absolute refractory). Wait for the upper tank to begin refilling. You can now flush again, but the intensity of the flushes increases as the upper tank refills (relative refractory)tank refills (relative refractory)
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Action Potential Conduction
If an AP is generated at the axon hillock, it will travel all the way down to the synaptic knob.
The manner in which it travels depends on whether the l d l dneuron is myelinated or unmyelinated.
Unmyelinated neurons undergo the continuous conductionf AP h li t d d l of an AP whereas myelinated neurons undergo saltatory
conduction of an AP.
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Continuous ConductionOccurs in unmyelinated axons.In this situation, the wave of de- and repolarization simply travels from one patch of membrane to the next adjacent p jpatch.APs moved in this fashion along the sarcolemma along the sarcolemma of a muscle fiber as well.Analogous to dominoes f llifalling.
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Saltatory ConductionOccurs in myelinated axons.
Saltare is a Latin word meaning “to leap.”
Recall that the myelin sheath is not completed. There exist myelin free regions along the axon, the nodes of Ranvier.
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Rates of AP Conduction1. Which do you think has a faster rate of AP conduction –
myelinated or unmyelinated axons?myelinated or unmyelinated axons?
2. Which do you think would conduct an AP faster – an axon with a large diameter or an axon with a small diameter?g
The answer to #1 is a myelinated axon. If you can’t see why, then answer thisThe answer to #1 is a myelinated axon. If you can t see why, then answer this question: could you move 100ft faster if you walked heel to toe or if you bounded in a way that there were 3ft in between your feet with each step?
The answer to #2 is an axon with a large diameter. If you can’t see why, then answer this question: could you move faster if you walked through a hallway that was 6ft wide or if you walked through a hallway that was 1ft wide?
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Types of Nerve Fibersyp1. Group A
Axons of the somatic sensory neurons and motor neurons serving the skin Axons of the somatic sensory neurons and motor neurons serving the skin, skeletal muscles, and joints.Large diameters and thick myelin sheaths.
How does this influence their AP conduction?
2. Group BType B are lightly myelinated and of intermediate diameter.
3. Group CType C are unmyelinated and have the smallest diameter.A t i t fib i th i l i l Autonomic nervous system fibers serving the visceral organs, visceral sensory fibers, and small somatic sensory fibers are Type B and Type C fibers.
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Now we know how signals get from one end of an axon to the
other, but how exactly do APs send information?yInfo can’t be encoded in AP size, since they’re “all or none.”
In the diagram on the right, notice the effect that the size of the graded potential has on the frequency of AP’sfrequency of AP sand on the quantity of NT released. The weak stimulus resulted in a small amt of NT releaserelease compared to the strong stimulus.
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Chemical Signals gOne neuron will transmit info to another neuron or to a muscle or gland cell by releasing chemicals called neurotransmitters.y g
The site of this chemical interplay is known as the synapse.An axon terminal (synaptic knob) will abut another cell, a neuron, muscle fiber, or gland cellgland cell.
This is the site of transduction – the conversion of an electrical signal into a chemical signal.
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Synaptic TransmissionTransmission
An AP reaches the axon terminal of the presynaptic terminal of the presynaptic cell and causes V-gated Ca2+
channels to open.Ca2+ rushes in binds to Ca rushes in, binds to regulatory proteins & initiates NT exocytosis.NTs diffuse across the NTs diffuse across the synaptic cleft and then bind to receptors on the postsynaptic membrane and p y pinitiate some sort of response on the postsynaptic cell.
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Effects of the Neurotransmitter
Different neurons can contain different NTs. .
Different postsynaptic cells may contain different receptors.Thus, the effects of an NT can vary., y
Some NTs cause cation channels to open, which results in a graded depolarization.
Some NTs cause anion channels to open, which results in a graded hyperpolarization.
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MODE OF ACTIONMODE OF ACTIONMODE OF ACTIONMODE OF ACTION
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Postsynaptic PotentialsPostsynaptic Potentials
§ Neurotransmitter receptors mediate changes in membrane potential according to:
§ The amount of neurotransmitter released§ Th t f ti th t itt i b d t t§ The amount of time the neurotransmitter is bound to receptors
§ The two types of postsynaptic potentials are:§ EPSP – excitatory postsynaptic potentials§ y p y p p§ IPSP – inhibitory postsynaptic potentials order
§ Spatial summation postsynaptic neuron is stimulated by a large number of§ Spatial summation – postsynaptic neuron is stimulated by a large number of terminals at the same time
§ IPSPs can also summate with EPSPs, canceling each other out
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Excitatory Postsynaptic Potentials(EPSP)Excitatory Postsynaptic Potentials(EPSP)
§§ EPSPs are graded potentials that can initiate an action potential in an axonEPSPs are graded potentials that can initiate an action potential in an axon§ U l h i ll t d h l§ Use only chemically gated channels§ Na + and K + flow in opposite directions at the same time
§§ Postsynaptic membranes do not generate action potentialsPostsynaptic membranes do not generate action potentials§§ y p g py p g p
Inhibitory Synapses and IPSPsInhibitory Synapses and IPSPs
§§ Neurotransmitter binding to a receptor at inhibitory synapses:Neurotransmitter binding to a receptor at inhibitory synapses:
§ Causes the membrane to become more permeable to potassium and chloride ions
§ Leaves the charge on the inner surface negative
§ Reduces the postsynaptic neuron’s ability to produce an action potential§ Reduces the postsynaptic neuron s ability to produce an action potential
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SummationSummation§ A single EPSP cannot induce an action potential
§ EPSPs must summate temporally or spatially to induce an action potential
§ Temporal summation – presynaptic neurons transmit impulses in rapidfire order
§ Spatial summation – postsynaptic neuron is stimulated by a large number of§ Spatial summation postsynaptic neuron is stimulated by a large number of terminals at the same time
§ IPSPs can also summate with EPSPs, canceling each other out
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EPSPs & IPSPsTypically, a single synaptic interaction will not create a graded depolarization strong enough to migrate to the axon strong enough to migrate to the axon hillock and induce the firing of an AP.
However, a graded depolarization will bring the neuronal VM closer to threshold. Thus it’s often referred to as an excitatory postsynaptic potential or EPSPThus, it s often referred to as an excitatory postsynaptic potential or EPSP.Graded hyperpolarizations bring the neuronal VM farther away from threshold and thus are referred to as inhibitory thus are referred to as inhibitory postsynaptic potentials or IPSPs.
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SummationOne EPSP is usually not strong enough to cause an AP.gHowever, EPSPs may be summed.
T l tiTemporal summationThe same presynaptic neuron stimulates the postsynaptic neuron
lti l ti i b i f i d Th d l i ti lti f th multiple times in a brief period. The depolarization resulting from the combination of all the EPSPs may be able to cause an AP.
Spatial summationMultiple neurons all stimulate a postsynaptic neuron resulting in a combination of EPSPs which may yield an AP
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Communication btwn neurons is Communication btwn neurons is not typically a one-to-one event.
Sometimes a single neuron branches and its collaterals synapse on multiple and its collaterals synapse on multiple target neurons. This is known as divergence.A single postsynaptic neuron may have A single postsynaptic neuron may have synapses with as many as 10,000 postsynaptic neurons. This is convergence.gCan you think of an advantage to having convergent and divergent circuits?
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N l f b Neurons may also form reverberating circuits.A chain of neurons where many give off collaterals that go back and synapse on previous neurons.
What might be a benefit of this arrangement?
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Neurotransmitter RemovalWhy did we want to remove ACh from the remove ACh from the neuro- muscular junction?How was ACh removed from the NMJ?NTs are removed from the synaptic cleft via:synaptic cleft via:
Enzymatic degradationDiffusionR kReuptake
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Phases of the Action PotentialPhases of the Action Potential1 – resting stateg
2 – depolarization phase
3 – repolarization phasep p
4 – hyperpolarization
Figure 11.12
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Absolute and Relative Refractory P i dPeriods
Figure 11.15
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Axonal ConductionAxonal Conduction•� Depolarization� Threshold� Axon Hillock� Na ions rush in resulting in:� Action potential;p ;� All or none phenomenon, high frequency� Afterpotentials; hyperpolarizing, depolarizing; slow frequencyslow frequency� Changes in membrane permeabilities� Propagation�
•Refractory periody p
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Postsynaptic PotentialsPostsynaptic Potentials
§ Neurotransmitter receptors mediate changes in membrane potential according to:
§ The amount of neurotransmitter released§ Th t f ti th t itt i b d t t§ The amount of time the neurotransmitter is bound to receptors
§ The two types of postsynaptic potentials are:§ EPSP – excitatory postsynaptic potentials§ y p y p p§ IPSP – inhibitory postsynaptic potentials order
§ Spatial summation postsynaptic neuron is stimulated by a large number of§ Spatial summation – postsynaptic neuron is stimulated by a large number of terminals at the same time
§ IPSPs can also summate with EPSPs, canceling each other out
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Excitatory Postsynaptic Potentials(EPSP)Excitatory Postsynaptic Potentials(EPSP)
§§ EPSPs are graded potentials that can initiate an action potential in an axonEPSPs are graded potentials that can initiate an action potential in an axon§ U l h i ll t d h l§ Use only chemically gated channels§ Na + and K + flow in opposite directions at the same time
§§ Postsynaptic membranes do not generate action potentialsPostsynaptic membranes do not generate action potentials§§ y p g py p g p
Inhibitory Synapses and IPSPsInhibitory Synapses and IPSPs
§§ Neurotransmitter binding to a receptor at inhibitory synapses:Neurotransmitter binding to a receptor at inhibitory synapses:
§ Causes the membrane to become more permeable to potassium and chloride ions
§ Leaves the charge on the inner surface negative
§ Reduces the postsynaptic neuron’s ability to produce an action potential§ Reduces the postsynaptic neuron s ability to produce an action potential
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SummationSummation§ A single EPSP cannot induce an action potential
§ EPSPs must summate temporally or spatially to induce an action potential
§ Temporal summation – presynaptic neurons transmit impulses in rapidfire order
§ Spatial summation – postsynaptic neuron is stimulated by a large number of§ Spatial summation postsynaptic neuron is stimulated by a large number of terminals at the same time
§ IPSPs can also summate with EPSPs, canceling each other out
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Synaptic Transmission� Post-synaptic potentials (PSP's);•� Excitatory� Excitatory•� Inhibitory•� Interaction�S i /I iSummation/Integration•� temporal•� spatial•� decremental conduction on dendrites and soma� decremental conduction on dendrites and soma� axon hillock is critical area at which threshold must be reached�After release of neurotransmitter,� t k� reuptake� degradation�Functional Synaptic Unitsy p
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Signals Carried by NeuronsSignals Carried by Neurons
In a resting (unstimulated) neuron, the membrane is polarized which means that the inner cytoplasmic side is negatively charged with respect to its outer, extracellular sideside
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Signals Carried by NeuronsSignals Carried by Neurons
When a neuron is stimulated the permeability of the plasma membrane changes at the site of the stimulus, allowing positive ions to rush in.
A l h i f f h b b l i As a result, the inner face of the membrane becomes less negative or depolarized
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Signals Carried by NeuronsSignals Carried by Neurons
Any part of the neuron depolarizes if stimulated, but at the axon alone this can result in the triggering of a nerve impulse or action potential
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Signals Carried by NeuronsSignals Carried by NeuronsWhen a nerve impulse or action potential develops the membrane is not only depolarized , but its polarity is completely reversed so it becomes negative externally and positive internallypositive internally
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Signals Carried by NeuronsSignals Carried by Neurons
Once begun, the nerve impulse travels rapidly down the entire length of the axon without decreasing in strength
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Signals Carried by NeuronsSignals Carried by Neurons
After the impulse has passed the membrane repolarizes itself
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Graded PotentialGraded PotentialIn humans, natural stimuli are not applied directly to axons, but to dendrites and the cell body which constitute the receptive zone of the neuron
When the membrane of this receptive zone is stimulated it does not undergo a polarit re ersal not undergo a polarity reversal
Instead it undergoes a local depolarization in which the inner surface of the membrane merely becomes less negativesurface of the membrane merely becomes less negative
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Graded PotentialGraded PotentialThis local depolarization is called a graded potential which spreads from the receptive zone to the axon hillock (trigger zone) decreasing in strength as it travels
If this depolarizing signal is strong enough when it reaches the initial segment of the a on it acts as the trigger that initiates an initial segment of the axon, it acts as the trigger that initiates an action potential in the axon
Signals from the receptive zone determine if the axon will fire Signals from the receptive zone determine if the axon will fire an impulse
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Synaptic PotentialSynaptic PotentialMost neurons in the body do not receive stimuli directly from the environment but are stimulated only by signals received at synapses from other neurons
Synaptic input influences impulse generation through either Synaptic input influences impulse generation through either excitatory or inhibitory synapses
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Synaptic PotentialSynaptic PotentialIn excitatory synapses, neurotransmitters released by presynaptic neurons alter the permeability of the postsysnaptic membrane to certain ions, this depolarizes the postsynapatic membrane and drives the postsynaptic neuron postsynapatic membrane and drives the postsynaptic neuron toward impulse generation
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Synaptic PotentialSynaptic PotentialInhibitory synapses cause the external surface of the postsynaptic membrane to become even more positive, thereby reducing the ability of the postsynaptic neuron to generate an action potentialgenerate an action potential
Thousands of excitatory and inhibitory synapses act on every neuron, competing to determine whether or not that neuron p gwill generate an impulse
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Neural IntegrationNeural IntegrationThe organization of the nervous system is hierarchical
The parts of the system must be integrated into a smoothly functioning whole
N l l f h b f Neuronal pools represent some of the basic patterns of communication with other parts of the nervous system
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Neuronal PoolsNeuronal pools are functional groups of groups of neurons that process and integrate incoming information information from other sources and
i i transmit it forward One incoming presynaptic fiber synapses with
Several different neurons in the pool. WhenIncoming fiber is excited it will excite somePostsynaptic neurons and facilitate others.
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Neuronal PoolsNeuronal PoolsNeurons most likely to generate impulses are h l l those most closely
associated with the incoming fiber because gthey receive the bulk of the synaptic
t tcontactsThese neurons are in the discharge zonethe discharge zone
Di h ZDischarge Zone
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Neuronal PoolsNeuronal PoolsNeurons farther away from the center are not excited to threshold by excited to threshold by the incoming fiber, but are facilitated and can
l b heasily brought to threshold by stimuli from another sourcefrom another sourceThe periphery of the pool is the facilitated zone
FacilitatedFacilitatedzone
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Neuronal PoolsNeuronal PoolsNote: The illustrations presented are a gross oversimplification of an actual neuron pool
Most neuron pools consist of thousands of neurons and include inhibitory as well as excitatory neurons include inhibitory as well as excitatory neurons